Distribution and characterization of Streptomyces species causing potato common scab in Germany

Field‐grown potatoes showing scab infections were sampled in two successive years and analysed for prevailing Streptomyces strains. In 2008 and 2009, 293 Streptomyces isolates were collected in Germany and analysed for morphology, pathogenicity and strain type. Isolates varied in mycelium colour, sporulation and pigmentation. Based on their morphology, no clear differentiation of species was possible. At the genetic level, sampled isolates, as well as a number of type strains from culture collections, were characterized by PCR using 16S rRNA‐specific primers and PCR‐RFLP of the 16S–23S internal transcribed spacer (ITS) region with Hpy99I. Using this fingerprinting approach, Streptomyces species could be differentiated genotypically. The data from this study show that diversity among scab‐causing species in Germany is much higher than previously thought. Isolates belonged to various Streptomyces spp. previously associated with common scab. This is apparently the first report of pathogenic strains of S. europaeiscabiei, S. stelliscabiei, S. acidiscabiei, S. turgidiscabiei and S. bottropensis within Germany. Streptomyces europaeiscabiei was the predominant species found. Other scab‐causing species were identified, but their local distribution was uneven. For most of the isolates, the presence of the txtAB gene was demonstrated, indicating pathogenicity. This analysis is one of the first reports to examine the distribution of common scab‐causing species in Germany.     

Development of PCR-based Detection Methods for the Quarantine Phytopathogen <Emphasis Type="Italic">Synchytrium endobioticum</Emphasis>, Causal Agent of Potato Wart Disease

PCR-based methods were developed for the detection and quantification of the potato pathogen Synchytrium endobioticum in soil extracts and in planta. PCR primers, based on the internal transcribed spacer region of the multi-copy gene rDNA were tested for specificity, sensitivity and reproducibility in conventional and real-time PCR assays. Soil extraction procedures compared included the Hendrickx centrifugation (HC) procedure, nested wet sieving (NWS) and a method used by the Plant Protection Service (PPS). The primers amplified a 472 bp product from S. endobioticum DNA, but did not amplify DNA from other potato pathogens, other plant pathogens, and related species. Standard cell disruption and DNA extraction and purification methods were optimized for amplification of S. endobioticum DNA from resting sporangia. DNA was successfully amplified from a single sporangium and equivalent DNA preparations from soil extracts. Low levels of target DNA in water did not amplify, possibly due to DNA loss during final purification steps. A real-time PCR assay, developed for soil-based extracts using primers and probe based on the rDNA gene sequences, involved co-amplification of target DNA along with an internal DNA fragment. Both conventional and real-time PCR methods performed well with HC- and NWS-extracts having a threshold sensitivity of 10 sporangia per PCR assay. Of the three soil extraction methods, only with the HC method could 100 g soil samples be efficiently processed in one single PCR assay. Such a high capacity assay could be useful for routine soil analysis in respect to disease risk assessments and to secure de-scheduling according to EPPO guidelines.     

Detection and quantification of Ilyonectria spp. associated with black‐foot disease of grapevine in nursery soils using multiplex nested PCR and quantitative PCR

Three nursery fields and three rootstock mother fields from commercial nurseries located in Comunidad Valenciana region (central‐eastern Spain) were surveyed in July 2011 to detect the presence and to quantify Ilyonectria spp. in the soil. In each field, ten soil samples were taken randomly with a soil probe at a depth of 10–30 cm, and 10–20 cm from the base of the plant. Three replicate subsamples (10 g each) were taken from each soil sample. DNA was extracted and a multiplex nested PCR with species‐specific primer pairs (Mac1/MaPa2, Lir1/Lir2 and Pau1/MaPa2) was used to identify the species present. Among the 180 soil DNA samples analysed, Ilyonectria spp. were detected in 172 of them. Ilyonectria macrodidyma complex was the most frequently detected, being identified in 141 samples from all the fields evaluated. However, I. liriodendri was detected in only 16 samples, but was present in all open‐root field nurseries and in two rootstock mother fields. In addition, quantitative PCR (qPCR) assays were done to assess the levels of I. liriodendri and I. macrodidyma‐complex DNA in the soil samples. Detection of Ilyonectria spp. DNA using qPCR correlated with the fields found positive with the nested multiplex PCR. DNA concentrations of Ilyonectria spp. ranged from 0·004 to 1904·8 pg μL^?1. In general, samples from rootstock mother fields showed the highest DNA concentrations. The ability to detect and quantify Ilyonectria spp. genomic DNA in soil samples from nursery fields and rootstock mother fields confirms soils from both field types as important inoculum sources for black‐foot pathogens.     

Development of a real‐time PCR method for the detection of the dagger nematodes Xiphinema index,X. diversicaudatum,X. vuittenezi and X. italiae,and for the quantification of X. index numbers

The ectoparasitic dagger nematodes Xiphinema index and Xiphinema diversicaudatum, often at low numbers in the soil, are vectors of grapevine nepoviruses, which cause huge agronomical problems for the vineyard industry. This study reports a method, based on real‐time PCR, for the specific detection of these species and of the closely related non‐vector species Xiphinema vuittenezi and Xiphinema italiae. Specific primers and TaqMan probes were designed from the ribosomal DNA internal transcribed spacer 1 (ITS1), enabling the specific detection of single individuals of each of the X. index, X. diversicaudatum, X. italiae and X. vuittenezi species whatever the nematode population. The specificity of detection and absence of false positive reaction were confirmed in samples of each species mixed with the three other Xiphinema species or mixed with nematodes representative from other genera (non‐plant‐parasitic Dorylaimida, Longidorus sp., Meloidogyne spp., Globodera spp. and Pratylenchus sp.). The method was shown to be valid for the relative quantification of X. index numbers through its use, from crude nematode extracts of soil samples, in a greenhouse assay of grapevine accessions ranging from highly susceptible to resistant. As an alternative to time‐consuming microscopic identification and counting, this real‐time PCR method will provide a fast, sensitive and reliable diagnostic and relative quantification technique for X. index nematodes extracted from fields or controlled conditions.     

Detection of Meloidogyne incognita and Pochonia chlamydosporia by fluorogenic molecular probes*

Fluorescent molecular probes were applied for detection of the plant parasitic nematode Meloidogyne incognita and the nematode‐egg parasitic fungus Pochonia chlamydosporia var. chlamydosporia. A region in the M. incognita rDNA including ITS2 was selected for amplification and recognition with a real‐time PCR assay, based on a combination of three specific motifs, each recognized by a specific fluorescent probe. Similarly, a Scorpion probe was designed for the RT‐PCR quantification of P. c. chlamydosporia. For this purpose, the ITS‐2 rDNA gene of the fungus was sequenced from a number of Italian isolates. A conserved region unique for P. c. chlamydosporia found in the ITS‐2 rDNA gene was used. The probes allowed recognition of single juveniles of M. incognita and of the mycelium‐ or soil‐extracted fungal DNA. The potentialities of the detection procedures are discussed.     

Quantification of Mirafiori lettuce big‐vein virus and its vector,Olpidium virulentus,from soil using real‐time PCR

Big vein disease of lettuce (Lactuca sativa) is an economically important disease transmitted through soil by Olpidium virulentus, and has occurred in most production areas worldwide. The disease is assumed to be caused by Mirafiori lettuce big‐vein virus (MiLBVV). To understand the dynamics of the virus and its vector, MiLBVV and O. virulentus were directly detected in soil. DNA and RNA were extracted from 5 g soil using a bead beating method, followed by purification using adsorption to a column. Detection and quantification were performed using real‐time PCR and a TaqMan probe that was prepared based on the CP region of MiLBVV and the rDNA‐ITS region of O. virulentus, respectively. Furthermore, using a visual assessment of the incidence rate of big vein disease on lettuce in agricultural fields, the C_t values of MiLBVV and O. virulentus from soil were also determined using real‐time PCR. The results showed that MiLBVV concentrations in the soil were high in the field, as also determined by a visual assessment of the incidence rate of big vein disease on lettuce. However, the amount of O. virulentus in soil was not directly correlated with the incidence of MiLBVV. From these results, it is suggested that the risk of lettuce crops developing big vein disease can be estimated using an index of the amount of MiLBVV in the soil.     

Isolation and characterization of Streptomyces species from potato common scab lesions in Norway

The present survey was conducted to isolate and characterize Streptomyces species from common scab lesions of potato in Norway. Bacteria were isolated from scab lesions on tubers sampled in two consecutive years at different locations in Norway spanning ～1400 km from south to north. In total, 957 independent isolations from individual tubers were performed, with 223 putative pathogenic isolates obtained from 29 different potato cultivars and 130 different fields. Streptomyces europaeiscabiei was the most abundant species isolated from common scab lesions (69%), while 31% of the isolates obtained were S. turgidiscabies. Streptomyces scabies was not found. Pathogenicity of selected Streptomyces isolates was tested on potato. The ability of the bacterial isolates to infect potato was consistent with the presence of the txtAB operon. The results revealed no pattern in geographical distribution of S. europaeiscabiei and S. turgidiscabies; both could be found in the same field and even the same lesion. Four different pathogenicity island (PAI) genotypes were detected amongst the txtAB positive isolates: nec1+/tomA+, nec1–/tomA+, nec1+/tomA? and nec1?/tomA?. The current findings demonstrate that there is genetic variability within species and that the species are not spread solely by clonal expansion. This is thought to be the most comprehensive survey of Streptomyces species that cause common scab of potato in a European country.     

Validation of a real‐time PCR method for the detection of Phytophthora ramorum1

To validate a real‐time PCR method for the detection of Phytophthora ramorum, an intra‐laboratory procedure was developed. The specificity of the TaqMan probe/primer sets was determined by carrying out real‐time PCR on total DNA extracted from pure culture of several Phytophthora species. The limit of detection and the potential effects of plant substrates were evaluated by conducting the test on total DNA from healthy plant materials (Rhododendron spp., Viburnum spp. and Pieris spp.) spiked with known amounts of P. ramorum genomic DNA. The PCR efficiency was estimated through the linear regression of the dilution curve. Precision of the TaqMan assay was assessed on material from a single artificially infected plant (Rhododendron spp.). Two kinds of tissues were tested: a severely infected twig and an apparently healthy leaf. Intra‐assay repeatability was evaluated on 10 replicates of the same DNA sample analysed in a single assay. Inter‐assay reproducibility was evaluated on the same DNA sample amplified over five separate assays while the intersample reproducibility was evaluated on separate DNA extractions of four samples from both plant tissues amplified in a single assay.     

A nested‐PCR method for rapid detection of Sclerotinia sclerotiorum on petals of oilseed rape (Brassica napus)

This study established a quick and accurate method to detect petal infection of oilseed rape (Brassica napus) by Sclerotinia sclerotiorum using a nested‐PCR technique. DNA samples were extracted from each petal using a microwave method, followed by two rounds of PCR amplification. The first‐round PCR amplification was performed using the universal fungal primer pair ITS4/ITS5, and the second‐round amplification with a specific primer pair XJJ21/XJJ222, which was designed using the single‐nucleotide polymorphisms among nuclear rDNA ITS sequences of Sclerotinia spp., Botrytis spp. and other selected fungi. The established technique is rapid and inexpensive, and has a high degree of specificity and sensitivity. This assay can distinguish Sclerotinia spp. from other fungi, including Botrytis cinerea, a closely related and frequent cohabitant on oilseed rape petals, and can detect 50 fg genomic DNA, five ascospores of S. sclerotiorumin vitro or 50 ascospores of S. sclerotiorum on one petal in approximately 6 h, even in the presence of a high background of oilseed rape DNA. This technique was successfully applied in detecting natural petal infections.     

A Phytophthora conserved transposon‐like DNA element as a potential target for soyabean root rot disease diagnosis

A transposon‐like element, A3aPro, with multiple copies in the Phytophthora sojae genome, was identified as a suitable detection target for this devastating soyabean root rot pathogen. The PCR primers TrapF1/TrapR1 were designed based on unique sequences derived from the transposon‐like sequence. A 267‐bp DNA fragment was amplified using this primer pair, the specificity of which was evaluated against 118 isolates of P. sojae, 72 isolates of 25 other Phytophthora spp., isolates of Pythium spp. and isolates of true fungi. In tests with P. sojae genomic DNA, detection sensitivities of 10 pg and 10 fg DNA were achieved in standard PCR (TrapF1/TrapR1) and nested PCR (TrapF1/TrapR1 and TrapF2/TrapR2), respectively. Meanwhile, PCR with TrapF1/TrapR1 primers detected the pathogen at the level of a single oospore, and even one zoospore. These primers also proved to be efficient in detecting pathogens from diseased soyabean tissues, residues and soils. In addition, real‐time quantitative PCR (qPCR) assays coupled with the TrapF1/TrapR1 primers were developed to detect and quantify the pathogen. The results demonstrated that the TrapF1/TrapR1 and TrapF2/TrapR2 primer‐based PCR assay provides a rapid and sensitive tool for the detection of P. sojae in plants and in production fields.     

In‐field distribution of Plasmodiophora brassicae measured using quantitative real‐time PCR

A protocol using real‐time polymerase chain reaction (PCR) for the direct detection and quantification of Plasmodiophora brassicae in soil samples was developed and used on naturally and artificially infested soil samples containing different concentrations of P. brassicae. Species‐specific primers and a TaqMan fluorogenic probe were designed to amplify a small region of P. brassicae ribosomal DNA. Total genomic DNA was extracted and purified from soil samples using commercial kits. The amount of pathogen DNA was quantified using a standard curve generated by including reactions containing different amounts of a plasmid carrying the P. brassicae target sequence. The PCR assay was optimized to give high amplification efficiency and three to four copies of the target DNA sequence were detected. Regression analysis showed that the standard curve was linear over at least six orders of magnitude (R² > 0·99) and that the amplification efficiency was >92%. The detection limit in soil samples corresponded to 500 resting spores g^?1 soil. The intersample reproducibility was similar to, or higher than, that of assays for other pathogens quantified in soil samples. Bait plants were used to validate the real‐time PCR assay. The protocol developed was used to investigate the spatial distribution of P. brassicae DNA in different fields and a significant difference was found between in‐field sampling points. The reproducibility of soil sampling was evaluated and showed no significant differences for samples with low levels of inoculum, whereas at higher levels differences occurred. Indicator kriging was used for mapping the probability of detecting P. brassicae within a 2‐ha area of a field. A threshold level of 5 fg plasmid DNA g^?1 soil, corresponding to approximately 3 × 10³P. brassicae resting spores g^?1 soil, is suggested for growing resistant cultivars. The results provide a robust and reliable technique for predicting the risk of disease development and for assessing the distribution of disease within fields.     

Development of a real‐time PCR assay for Pseudomonas cichorii,the causal agent of midrib rot in greenhouse‐grown lettuce,and its detection in irrigating water

Midrib rot is an emerging disease in greenhouse production of lettuce caused by Pseudomonas cichorii, and probably introduced through contaminated irrigation water. Concentrations of 100 CFU mL^?1 are enough to induce the typical midrib rot symptoms. A sensitive real‐time PCR assay was developed, based on a 90‐bp amplicon from the pathogenicity gene cluster hrcRST and a Taqman Minor Groove Binding probe. Specificity of the assay was tested with 39 P. cichorii strains, including the type strain, and 89 strains from 83 other Pseudomonas species. The relationship between detection signals and P. cichorii DNA concentrations was linear over 6‐logs. Detection threshold with excellent reproducibility was 500 fg of DNA or about 70 genome copies. Sample preparation and DNA isolation were optimized to allow detection in 1 L water samples. The assay was first evaluated with greenhouse irrigation water spiked with serial dilutions of P. cichorii. The calculated cell numbers obtained with real‐time PCR were 10‐fold lower than plate counts of actual spiked cells. However, the assay consistently detected 100 CFU per reaction, corresponding to the detection of 1 CFU mL^?1 of irrigation water, which is well below the concentration needed for midrib rot infection. Finally, the assay proved to be valuable for detecting infective P. cichorii concentrations in the irrigation water of a commercial lettuce production greenhouse.     

Detection of botryosphaeriaceous species in environmental samples using a multi‐species primer pair

Botryosphaeriaceous species are significant grapevine trunk pathogens worldwide, which can be difficult to identify to species level using conventional morphological methods. This study developed and optimized a quick, reliable molecular identification method that could facilitate investigations into the epidemiology of these diseases in vineyards. The multi‐species primers, BOT100F and BOT472R, amplified a 371–372 bp portion of the rRNA gene region from the six botryosphaeriaceous species commonly found in New Zealand vineyards. In silico analysis indicated that they would amplify DNA from six of the 12 lineages of the Botryosphaeriaceae, including all of the main species pathogenic to grapevines. A detection sensitivity of 1 and 0·1 pg DNA in standard and nested PCR, respectively, was achieved and this was calculated as equivalent to 2·5 conidia. Validation of the primers for environmental samples showed that their specificity was not compromized by the presence of competing DNA templates extracted from wood and soil. Single stranded conformational polymorphism (SSCP) analysis of the amplicons could resolve Neofusicoccum australe, N. luteum, Diplodia mutila and D. seriata, but did not differentiate between N. parvum and N. ribis. The optimized PCR‐SSCP was used to identify botryosphaeriaceous species present in rainwater traps collected over 1 year in a vineyard known to contain infected vines. It could detect multiple species in individual samples and demonstrated differences in the dispersal patterns of conidia from different species. Given the specificity and sensitivity of this method it could prove useful in epidemiology studies involving the numerous botryosphaeriaceous species that infect a wide range of host species.     

Development of a quantitative real‐time PCR assay for Phytophthora infestans and its applicability to leaf,tuber and soil samples

A sensitive real‐time polymerase chain reaction (PCR) assay was developed for the quantification of Phytophthora infestans, the cause of foliar and tuber late blight in potato. A primer pair (PinfTQF/PinfTQR) and a fluorogenic probe (PinfTQPR) were designed to perform a quantitative assay for the detection of P. infestans in leaves, tubers and soils. The assay was shown to be specific to P. infestans and the very closely taxonomically related non‐potato pathogen species P. mirabilis, P. phaseoli and P. ipomoea, but did not detect the potato pathogens P. erythroseptica and P. nicotianae. The assay was able to reliably detect P. infestans DNA at 100 fg per reaction and was effective in quantifying P. infestans in infected leaf tissue from 24 h after inoculation and also in infected symptomless tubers and diseased tubers. Attempts to detect oospores of P. infestans in naturally and artificially infested soil samples are described and compared with baiting tests and previous literature. It was not possible to detect oospores in soil samples due to problems with DNA extraction from the oospores themselves. However, the assay was shown to detect even very low levels of asexual inoculum (sporangia and mycelium) in soil. This work assembles all the necessary features of a quantitative P. infestans assay, which have previously been somewhat disparate: the sensitivity, specificity and quantitation are fully validated, the assay is shown to work in common applications in leaf and tuber tissue and the problems with P. infestans oospore detection are explored and tested experimentally.     

Identification of ALS inhibitor‐resistant Amaranthus biotypes using polymerase chain reaction amplification of specific alleles

Summary Polymerase chain reaction (PCR) amplification of specific alleles (PASA) was adapted as a molecular marker‐based method for the rapid detection of point mutations in Amaranthus retroflexus and Amaranthus rudis leading to ALS inhibitor resistance. Two pairs of primers were designed for the specific amplification of alleles of the ALS gene of susceptible and resistant biotypes. The allele‐specific primer matched the desired allele, but mismatched the different allele at its 3′ end. Differentiation was carried out by comparison of the amplified DNA fragments in gel electrophoresis after PASA‐PCR. In A. rudis, differentiation was possible with one PCR and genomic DNA as probe. A ‘nested’ PCR was necessary for the differentiation of sensitive and resistant A. retroflexus. PASA is useful for the identification of resistant weed biotypes and also as a monitoring tool to map resistance occurrence and distribution. Advantages include the fast and clear separation of those plants with and without mutations at an early stage of development, its easy and consistent performance and quick results compared with existing resistance detection tests. These advantages, when combined with management strategies, enable further activities to reduce herbicide resistance.     

Development of Specific PCR Primers for Identification and Detection of Rhizopycnis vagum

Rhizopycnis vagum is a recently described coelomycete known to belong to the complex of root rot pathogens contributing to vine decline of cucurbits in several parts of the world. However, the fungus has also been reported to infect tomato, and as an endophytic associate of mycorrhizal roots of wild, asymptomatic Pinus halepensis and Rosmarinus officinalis plants in Italy. To accelerate epidemiological and ecological investigations on this fungus, a PCR primer pair was developed. Primers Rv1-F and Rv1-R were designed, based on alignment of internal transcribed spacer (ITS) sequences (ITS1-5.8S-ITS2), which amplified a 396-bp fragment from all R. vagum isolates tested, including isolates pathogenic to melons and endophytic isolates from mycorrhizae. Specificity of the primer pair was verified both in silico (BLAST searches using each primer string as a query) and in PCR assays, where the primers failed to amplify DNA from any isolate of fungi taxonomically related to R. vagum (e.g. Massarina walkeri and Stagonospora spp.) and other vine decline and common soilborne pathogens (e.g. Monasporascus cannonballus, Acremonium cucurbitacearum, Fusarium spp. and Rhizoctonia solani). Under optimum conditions, detectable amplification of the specific sequence required 0.05 pg of target DNA. Amplification of the expected 369-bp fragment was also obtained from DNA root extracts of nearly asymptomatic Cucumis melo plants inoculated with R. vagum under greenhouse conditions.     

Genetic diversity of Fusarium oxysporum and related species pathogenic on tomato in Algeria and other Mediterranean countries

In order to characterize the pathogen(s) responsible for the outbreak of fusarium diseases in Algeria, 48 Fusarium spp. isolates were collected from diseased tomato in Algeria and compared with 58 isolates of Fusarium oxysporum originating from seven other Mediterranean countries and 24 reference strains. Partial sequences of the translation elongation factor EF‐1α gene enabled identification of 27 isolates as F. oxysporum, 18 as F. commune and three as F. redolens among the Algerian isolates. Pathogenicity tests confirmed that all isolates were pathogenic on tomato, with disease incidence greater at 28°C than at 24°C. All isolates were characterized using intergenic spacer (IGS) DNA typing, vegetative compatibility group (VCG) and PCR detection of the SIX1 (secreted in xylem 1) gene specific to F. oxysporum f. sp. lycopersici (FOL). No DNA polymorphisms were detected in the isolates of F. redolens or F. commune. In contrast, the 27 Algerian isolates of F. oxysporum were shown to comprise nine IGS types and 13 VCGs, including several potentially new VCGs. As none of the isolates was scored as SIX1+, the 27 isolates could be assigned to F. oxysporum f. sp. radicis‐lycopersici (FORL). Isolates from Tunisia were also highly diverse but genetically distinct from the Algerian isolates. Several Tunisian isolates were identified as FOL by a PCR that detected the presence of SIX1. The results show that isolates from European countries were less diverse than those from Tunisia. Given the difference between Algerian populations and populations in other Mediterranean countries, newly emergent pathogenic forms could have evolved from local non‐pathogenic populations in Algeria.     

Genotypic and phenotypic characterization of Streptomyces species associated with potato crops in the central part of Colombia

In Colombia, Streptomyces scabiei (syn. S. scabies) is commonly believed to be the causal organism of scab disease in local potato crops. However, very little is known about this organism and about the diversity and pathogenicity of the Streptomyces species associated with potato crops in Colombia. This study, therefore, aimed to elucidate aspects regarding the diversity of these bacteria associated with potato crops in a particular region of Colombia and evaluate their pathogenicity. We obtained 33 isolates of Streptomyces from netted, superficial and deep-pitted potato scab lesions from two main potato-producing regions in Colombia. Of these, 17 were pathogenic based on in vitro and in planta assays. None of these isolates carried the txtA, txtB, or nec1 genes, commonly associated with pathogenicity in Streptomyces, and characteristic of the pathogenicity island (PAI). We also characterized all isolates based on phenotypic characteristics and analysed their phylogenetic relationships using the 16S rRNA, atpD, recA, rpoB, and trpB genes. The isolates were highly diverse, placed in nine clades with 15 different phenotypes. The 17 pathogenic isolates were placed into three clades, namely S. pratensis, S. xiamenensis, and unknown species. This study is a preliminary investigation towards understanding scab disease in Colombia through the study of both pathogenic and nonpathogenic species present in scab disease lesions in potatoes. Also, this is the first report of Streptomyces species associated with potato tubers in Colombia.     

雪松疫霉(Phytophthora lateralis)的快速分子检测

由雪松疫霉(Phytophthora lateralis)引起的疫病是一类植物检疫性病害。为建立该病原菌的快速检测技术,本文比较分析了雪松疫霉和其他疫霉的tRNA序列,在此基础上设计了一对检测雪松疫霉的特异性引物T1/T2,该对引物从雪松疫霉中扩增得到1条192 bp的条带,而其他15种疫霉和其他真菌菌株均无扩增条带,表明该对引物对雪松疫霉具有特异性。在25μL PCR反应体系中,引物T1/T2检测灵敏度为10 pg基因组DNA;而以引物T3/T4和T1/T2进行巢式PCR扩增,能够检测到1 fg基因组DNA,使检测灵敏度提高了10 000倍。该检测体系对灭菌水中游动孢子的检测灵敏度可达0.5个游动孢子,对人工接种发病的植物组织能够特异性地检测到该病原菌。此外,进一步建立了该病原菌的实时荧光定量PCR检测体系。